A Novel Material for In Situ Construction on Mars: Experiments and Numerical Simulations

TL;DR

This paper introduces a new Martian soil-based construction material using sulfur, demonstrating high strength, recyclability, and suitability for in situ Mars construction through experiments and simulations.

Contribution

It develops and characterizes a novel Martian Concrete made from simulated Martian soil and sulfur, with optimized mixing proportions and validated through experiments and LDPM simulations.

Findings

Martian Concrete's strength exceeds 50 MPa.

Optimal sulfur content improves mechanical properties.

Simulation accurately models material response.

Abstract

A significant step in space exploration during the 21st century will be human settlement on Mars. Instead of transporting all the construction materials from Earth to the red planet with incredibly high cost, using Martian soil to construct a site on Mars is a superior choice. Knowing that Mars has long been considered a "sulfur-rich planet", a new construction material composed of simulated Martian soil and molten sulfur is developed. In addition to the raw material availability for producing sulfur concrete and a strength reaching similar or higher levels of conventional cementitious concrete, fast curing, low temperature sustainability, acid and salt environment resistance, 100% recyclability are appealing superior characteristics of the developed Martian Concrete. In this study, different percentages of sulfur are investigated to obtain the optimal mixing proportions. Three point bending, unconfined compression and splitting tests were conducted to determine strength development, strength variability, and failure mechanisms. The test results show that the strength of Martian Concrete doubles that of sulfur concrete utilizing regular sand. It is also shown that the particle size distribution plays an important role in the mixture's final strength. Furthermore, since Martian soil is metal rich, sulfates and, potentially, polysulfates are also formed during high temperature mixing, which might contribute to the high strength. The optimal mix developed as Martian Concrete has an unconfined compressive strength of above 50 MPa. The formulated Martian Concrete is simulated by the Lattice Discrete Particle Model (LDPM), which exhibits excellent ability in modeling the material response under various loading conditions.